lvts_thermal.c 60 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (c) 2023 MediaTek Inc.
  4. * Author: Balsam CHIHI <bchihi@baylibre.com>
  5. */
  6. #include <linux/clk.h>
  7. #include <linux/clk-provider.h>
  8. #include <linux/delay.h>
  9. #include <linux/debugfs.h>
  10. #include <linux/init.h>
  11. #include <linux/interrupt.h>
  12. #include <linux/iopoll.h>
  13. #include <linux/kernel.h>
  14. #include <linux/nvmem-consumer.h>
  15. #include <linux/of.h>
  16. #include <linux/platform_device.h>
  17. #include <linux/reset.h>
  18. #include <linux/thermal.h>
  19. #include <dt-bindings/thermal/mediatek,lvts-thermal.h>
  20. #include "../thermal_hwmon.h"
  21. #define LVTS_MONCTL0(__base) (__base + 0x0000)
  22. #define LVTS_MONCTL1(__base) (__base + 0x0004)
  23. #define LVTS_MONCTL2(__base) (__base + 0x0008)
  24. #define LVTS_MONINT(__base) (__base + 0x000C)
  25. #define LVTS_MONINTSTS(__base) (__base + 0x0010)
  26. #define LVTS_MONIDET0(__base) (__base + 0x0014)
  27. #define LVTS_MONIDET1(__base) (__base + 0x0018)
  28. #define LVTS_MONIDET2(__base) (__base + 0x001C)
  29. #define LVTS_MONIDET3(__base) (__base + 0x0020)
  30. #define LVTS_H2NTHRE(__base) (__base + 0x0024)
  31. #define LVTS_HTHRE(__base) (__base + 0x0028)
  32. #define LVTS_OFFSETH(__base) (__base + 0x0030)
  33. #define LVTS_OFFSETL(__base) (__base + 0x0034)
  34. #define LVTS_MSRCTL0(__base) (__base + 0x0038)
  35. #define LVTS_MSRCTL1(__base) (__base + 0x003C)
  36. #define LVTS_TSSEL(__base) (__base + 0x0040)
  37. #define LVTS_CALSCALE(__base) (__base + 0x0048)
  38. #define LVTS_ID(__base) (__base + 0x004C)
  39. #define LVTS_CONFIG(__base) (__base + 0x0050)
  40. #define LVTS_EDATA00(__base) (__base + 0x0054)
  41. #define LVTS_EDATA01(__base) (__base + 0x0058)
  42. #define LVTS_EDATA02(__base) (__base + 0x005C)
  43. #define LVTS_EDATA03(__base) (__base + 0x0060)
  44. #define LVTS_MSROFT(__base) (__base + 0x006C)
  45. #define LVTS_ATP0(__base) (__base + 0x0070)
  46. #define LVTS_ATP1(__base) (__base + 0x0074)
  47. #define LVTS_ATP2(__base) (__base + 0x0078)
  48. #define LVTS_ATP3(__base) (__base + 0x007C)
  49. #define LVTS_MSR0(__base) (__base + 0x0090)
  50. #define LVTS_MSR1(__base) (__base + 0x0094)
  51. #define LVTS_MSR2(__base) (__base + 0x0098)
  52. #define LVTS_MSR3(__base) (__base + 0x009C)
  53. #define LVTS_IMMD0(__base) (__base + 0x00A0)
  54. #define LVTS_IMMD1(__base) (__base + 0x00A4)
  55. #define LVTS_IMMD2(__base) (__base + 0x00A8)
  56. #define LVTS_IMMD3(__base) (__base + 0x00AC)
  57. #define LVTS_PROTCTL(__base) (__base + 0x00C0)
  58. #define LVTS_PROTTA(__base) (__base + 0x00C4)
  59. #define LVTS_PROTTB(__base) (__base + 0x00C8)
  60. #define LVTS_PROTTC(__base) (__base + 0x00CC)
  61. #define LVTS_CLKEN(__base) (__base + 0x00E4)
  62. #define LVTS_PERIOD_UNIT 0
  63. #define LVTS_GROUP_INTERVAL 0
  64. #define LVTS_FILTER_INTERVAL 0
  65. #define LVTS_SENSOR_INTERVAL 0
  66. #define LVTS_HW_FILTER 0x0
  67. #define LVTS_TSSEL_CONF 0x13121110
  68. #define LVTS_CALSCALE_CONF 0x300
  69. #define LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR0 BIT(3)
  70. #define LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR1 BIT(8)
  71. #define LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR2 BIT(13)
  72. #define LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR3 BIT(25)
  73. #define LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR0 BIT(2)
  74. #define LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR1 BIT(7)
  75. #define LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR2 BIT(12)
  76. #define LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR3 BIT(24)
  77. #define LVTS_INT_SENSOR0 0x0009001F
  78. #define LVTS_INT_SENSOR1 0x001203E0
  79. #define LVTS_INT_SENSOR2 0x00247C00
  80. #define LVTS_INT_SENSOR3 0x1FC00000
  81. #define LVTS_SENSOR_MAX 4
  82. #define LVTS_GOLDEN_TEMP_MAX 62
  83. #define LVTS_GOLDEN_TEMP_DEFAULT 50
  84. #define LVTS_COEFF_A_MT8195 -250460
  85. #define LVTS_COEFF_B_MT8195 250460
  86. #define LVTS_COEFF_A_MT7987 -204650
  87. #define LVTS_COEFF_B_MT7987 204650
  88. #define LVTS_COEFF_A_MT7988 -204650
  89. #define LVTS_COEFF_B_MT7988 204650
  90. #define LVTS_COEFF_A_MT8196 391460
  91. #define LVTS_COEFF_B_MT8196 -391460
  92. #define LVTS_MSR_OFFSET_MT8196 -984
  93. #define LVTS_MSR_READ_TIMEOUT_US 400
  94. #define LVTS_MSR_READ_WAIT_US (LVTS_MSR_READ_TIMEOUT_US / 2)
  95. #define LVTS_MINIMUM_THRESHOLD 20000
  96. #define LVTS_MAX_CAL_OFFSETS 3
  97. #define LVTS_NUM_CAL_OFFSETS_MT7988 3
  98. #define LVTS_NUM_CAL_OFFSETS_MT8196 2
  99. static int golden_temp = LVTS_GOLDEN_TEMP_DEFAULT;
  100. static int golden_temp_offset;
  101. enum lvts_msr_mode {
  102. LVTS_MSR_IMMEDIATE_MODE,
  103. LVTS_MSR_FILTERED_MODE,
  104. LVTS_MSR_ATP_MODE,
  105. };
  106. struct lvts_sensor_data {
  107. int dt_id;
  108. u8 cal_offsets[LVTS_MAX_CAL_OFFSETS];
  109. };
  110. struct lvts_ctrl_data {
  111. struct lvts_sensor_data lvts_sensor[LVTS_SENSOR_MAX];
  112. u8 valid_sensor_mask;
  113. int offset;
  114. enum lvts_msr_mode mode;
  115. };
  116. #define VALID_SENSOR_MAP(s0, s1, s2, s3) \
  117. .valid_sensor_mask = (((s0) ? BIT(0) : 0) | \
  118. ((s1) ? BIT(1) : 0) | \
  119. ((s2) ? BIT(2) : 0) | \
  120. ((s3) ? BIT(3) : 0))
  121. #define lvts_for_each_valid_sensor(i, lvts_ctrl) \
  122. for ((i) = 0; (i) < LVTS_SENSOR_MAX; (i)++) \
  123. if (!((lvts_ctrl)->valid_sensor_mask & BIT(i))) \
  124. continue; \
  125. else
  126. struct lvts_platform_ops {
  127. int (*lvts_raw_to_temp)(u32 raw_temp, int temp_factor);
  128. u32 (*lvts_temp_to_raw)(int temperature, int temp_factor);
  129. };
  130. struct lvts_data {
  131. const struct lvts_ctrl_data *lvts_ctrl;
  132. const struct lvts_platform_ops *ops;
  133. const u32 *conn_cmd;
  134. const u32 *init_cmd;
  135. int num_cal_offsets;
  136. int num_lvts_ctrl;
  137. int num_conn_cmd;
  138. int num_init_cmd;
  139. int temp_factor;
  140. int temp_offset;
  141. int gt_calib_bit_offset;
  142. unsigned int def_calibration;
  143. u16 msr_offset;
  144. };
  145. struct lvts_sensor {
  146. struct thermal_zone_device *tz;
  147. void __iomem *msr;
  148. void __iomem *base;
  149. int id;
  150. int dt_id;
  151. int low_thresh;
  152. int high_thresh;
  153. };
  154. struct lvts_ctrl {
  155. struct lvts_sensor sensors[LVTS_SENSOR_MAX];
  156. const struct lvts_data *lvts_data;
  157. u32 calibration[LVTS_SENSOR_MAX];
  158. u8 valid_sensor_mask;
  159. int mode;
  160. void __iomem *base;
  161. int low_thresh;
  162. int high_thresh;
  163. };
  164. struct lvts_domain {
  165. struct lvts_ctrl *lvts_ctrl;
  166. struct reset_control *reset;
  167. struct clk *clk;
  168. int num_lvts_ctrl;
  169. void __iomem *base;
  170. size_t calib_len;
  171. u8 *calib;
  172. #ifdef CONFIG_DEBUG_FS
  173. struct dentry *dom_dentry;
  174. #endif
  175. };
  176. #ifdef CONFIG_MTK_LVTS_THERMAL_DEBUGFS
  177. #define LVTS_DEBUG_FS_REGS(__reg) \
  178. { \
  179. .name = __stringify(__reg), \
  180. .offset = __reg(0), \
  181. }
  182. static const struct debugfs_reg32 lvts_regs[] = {
  183. LVTS_DEBUG_FS_REGS(LVTS_MONCTL0),
  184. LVTS_DEBUG_FS_REGS(LVTS_MONCTL1),
  185. LVTS_DEBUG_FS_REGS(LVTS_MONCTL2),
  186. LVTS_DEBUG_FS_REGS(LVTS_MONINT),
  187. LVTS_DEBUG_FS_REGS(LVTS_MONINTSTS),
  188. LVTS_DEBUG_FS_REGS(LVTS_MONIDET0),
  189. LVTS_DEBUG_FS_REGS(LVTS_MONIDET1),
  190. LVTS_DEBUG_FS_REGS(LVTS_MONIDET2),
  191. LVTS_DEBUG_FS_REGS(LVTS_MONIDET3),
  192. LVTS_DEBUG_FS_REGS(LVTS_H2NTHRE),
  193. LVTS_DEBUG_FS_REGS(LVTS_HTHRE),
  194. LVTS_DEBUG_FS_REGS(LVTS_OFFSETH),
  195. LVTS_DEBUG_FS_REGS(LVTS_OFFSETL),
  196. LVTS_DEBUG_FS_REGS(LVTS_MSRCTL0),
  197. LVTS_DEBUG_FS_REGS(LVTS_MSRCTL1),
  198. LVTS_DEBUG_FS_REGS(LVTS_TSSEL),
  199. LVTS_DEBUG_FS_REGS(LVTS_CALSCALE),
  200. LVTS_DEBUG_FS_REGS(LVTS_ID),
  201. LVTS_DEBUG_FS_REGS(LVTS_CONFIG),
  202. LVTS_DEBUG_FS_REGS(LVTS_EDATA00),
  203. LVTS_DEBUG_FS_REGS(LVTS_EDATA01),
  204. LVTS_DEBUG_FS_REGS(LVTS_EDATA02),
  205. LVTS_DEBUG_FS_REGS(LVTS_EDATA03),
  206. LVTS_DEBUG_FS_REGS(LVTS_MSROFT),
  207. LVTS_DEBUG_FS_REGS(LVTS_ATP0),
  208. LVTS_DEBUG_FS_REGS(LVTS_ATP1),
  209. LVTS_DEBUG_FS_REGS(LVTS_ATP2),
  210. LVTS_DEBUG_FS_REGS(LVTS_ATP3),
  211. LVTS_DEBUG_FS_REGS(LVTS_MSR0),
  212. LVTS_DEBUG_FS_REGS(LVTS_MSR1),
  213. LVTS_DEBUG_FS_REGS(LVTS_MSR2),
  214. LVTS_DEBUG_FS_REGS(LVTS_MSR3),
  215. LVTS_DEBUG_FS_REGS(LVTS_IMMD0),
  216. LVTS_DEBUG_FS_REGS(LVTS_IMMD1),
  217. LVTS_DEBUG_FS_REGS(LVTS_IMMD2),
  218. LVTS_DEBUG_FS_REGS(LVTS_IMMD3),
  219. LVTS_DEBUG_FS_REGS(LVTS_PROTCTL),
  220. LVTS_DEBUG_FS_REGS(LVTS_PROTTA),
  221. LVTS_DEBUG_FS_REGS(LVTS_PROTTB),
  222. LVTS_DEBUG_FS_REGS(LVTS_PROTTC),
  223. LVTS_DEBUG_FS_REGS(LVTS_CLKEN),
  224. };
  225. static void lvts_debugfs_exit(void *data)
  226. {
  227. struct lvts_domain *lvts_td = data;
  228. debugfs_remove_recursive(lvts_td->dom_dentry);
  229. }
  230. static int lvts_debugfs_init(struct device *dev, struct lvts_domain *lvts_td)
  231. {
  232. struct debugfs_regset32 *regset;
  233. struct lvts_ctrl *lvts_ctrl;
  234. struct dentry *dentry;
  235. char name[64];
  236. int i;
  237. lvts_td->dom_dentry = debugfs_create_dir(dev_name(dev), NULL);
  238. if (IS_ERR(lvts_td->dom_dentry))
  239. return 0;
  240. for (i = 0; i < lvts_td->num_lvts_ctrl; i++) {
  241. lvts_ctrl = &lvts_td->lvts_ctrl[i];
  242. sprintf(name, "controller%d", i);
  243. dentry = debugfs_create_dir(name, lvts_td->dom_dentry);
  244. if (IS_ERR(dentry))
  245. continue;
  246. regset = devm_kzalloc(dev, sizeof(*regset), GFP_KERNEL);
  247. if (!regset)
  248. continue;
  249. regset->base = lvts_ctrl->base;
  250. regset->regs = lvts_regs;
  251. regset->nregs = ARRAY_SIZE(lvts_regs);
  252. debugfs_create_regset32("registers", 0400, dentry, regset);
  253. }
  254. return devm_add_action_or_reset(dev, lvts_debugfs_exit, lvts_td);
  255. }
  256. #else
  257. static inline int lvts_debugfs_init(struct device *dev,
  258. struct lvts_domain *lvts_td)
  259. {
  260. return 0;
  261. }
  262. #endif
  263. static int lvts_raw_to_temp(u32 raw_temp, const struct lvts_data *lvts_data)
  264. {
  265. return lvts_data->ops->lvts_raw_to_temp(raw_temp & 0xFFFF, lvts_data->temp_factor);
  266. }
  267. static u32 lvts_temp_to_raw(int temperature, const struct lvts_data *lvts_data)
  268. {
  269. return lvts_data->ops->lvts_temp_to_raw(temperature, lvts_data->temp_factor);
  270. }
  271. static int lvts_raw_to_temp_mt7988(u32 raw_temp, int temp_factor)
  272. {
  273. int temperature;
  274. temperature = ((s64)(raw_temp & 0xFFFF) * temp_factor) >> 14;
  275. temperature += golden_temp_offset;
  276. return temperature;
  277. }
  278. static u32 lvts_temp_to_raw_mt7988(int temperature, int temp_factor)
  279. {
  280. u32 raw_temp = ((s64)(golden_temp_offset - temperature)) << 14;
  281. raw_temp = div_s64(raw_temp, -temp_factor);
  282. return raw_temp;
  283. }
  284. static u32 lvts_temp_to_raw_mt8196(int temperature, int temp_factor)
  285. {
  286. u32 raw_temp;
  287. raw_temp = temperature - golden_temp_offset;
  288. return div_s64((s64)temp_factor << 14, raw_temp);
  289. }
  290. static int lvts_get_temp(struct thermal_zone_device *tz, int *temp)
  291. {
  292. struct lvts_sensor *lvts_sensor = thermal_zone_device_priv(tz);
  293. struct lvts_ctrl *lvts_ctrl = container_of(lvts_sensor, struct lvts_ctrl,
  294. sensors[lvts_sensor->id]);
  295. const struct lvts_data *lvts_data = lvts_ctrl->lvts_data;
  296. void __iomem *msr = lvts_sensor->msr;
  297. u32 value;
  298. int rc;
  299. /*
  300. * Measurement registers:
  301. *
  302. * LVTS_MSR[0-3] / LVTS_IMMD[0-3]
  303. *
  304. * Bits:
  305. *
  306. * 32-17: Unused
  307. * 16 : Valid temperature
  308. * 15-0 : Raw temperature
  309. */
  310. rc = readl_poll_timeout(msr, value, value & BIT(16),
  311. LVTS_MSR_READ_WAIT_US, LVTS_MSR_READ_TIMEOUT_US);
  312. /*
  313. * As the thermal zone temperature will read before the
  314. * hardware sensor is fully initialized, we have to check the
  315. * validity of the temperature returned when reading the
  316. * measurement register. The thermal controller will set the
  317. * valid bit temperature only when it is totally initialized.
  318. *
  319. * Otherwise, we may end up with garbage values out of the
  320. * functionning temperature and directly jump to a system
  321. * shutdown.
  322. */
  323. if (rc)
  324. return -EAGAIN;
  325. *temp = lvts_raw_to_temp(value, lvts_data);
  326. return 0;
  327. }
  328. static void lvts_update_irq_mask(struct lvts_ctrl *lvts_ctrl)
  329. {
  330. static const u32 high_offset_inten_masks[] = {
  331. LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR0,
  332. LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR1,
  333. LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR2,
  334. LVTS_MONINT_OFFSET_HIGH_INTEN_SENSOR3,
  335. };
  336. static const u32 low_offset_inten_masks[] = {
  337. LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR0,
  338. LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR1,
  339. LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR2,
  340. LVTS_MONINT_OFFSET_LOW_INTEN_SENSOR3,
  341. };
  342. u32 value = 0;
  343. int i;
  344. value = readl(LVTS_MONINT(lvts_ctrl->base));
  345. lvts_for_each_valid_sensor(i, lvts_ctrl) {
  346. if (lvts_ctrl->sensors[i].high_thresh == lvts_ctrl->high_thresh
  347. && lvts_ctrl->sensors[i].low_thresh == lvts_ctrl->low_thresh) {
  348. /*
  349. * The minimum threshold needs to be configured in the
  350. * OFFSETL register to get working interrupts, but we
  351. * don't actually want to generate interrupts when
  352. * crossing it.
  353. */
  354. if (lvts_ctrl->low_thresh == -INT_MAX) {
  355. value &= ~low_offset_inten_masks[i];
  356. value |= high_offset_inten_masks[i];
  357. } else {
  358. value |= low_offset_inten_masks[i] | high_offset_inten_masks[i];
  359. }
  360. } else {
  361. value &= ~(low_offset_inten_masks[i] | high_offset_inten_masks[i]);
  362. }
  363. }
  364. writel(value, LVTS_MONINT(lvts_ctrl->base));
  365. }
  366. static bool lvts_should_update_thresh(struct lvts_ctrl *lvts_ctrl, int high)
  367. {
  368. int i;
  369. if (high > lvts_ctrl->high_thresh)
  370. return true;
  371. lvts_for_each_valid_sensor(i, lvts_ctrl)
  372. if (lvts_ctrl->sensors[i].high_thresh == lvts_ctrl->high_thresh
  373. && lvts_ctrl->sensors[i].low_thresh == lvts_ctrl->low_thresh)
  374. return false;
  375. return true;
  376. }
  377. static int lvts_set_trips(struct thermal_zone_device *tz, int low, int high)
  378. {
  379. struct lvts_sensor *lvts_sensor = thermal_zone_device_priv(tz);
  380. struct lvts_ctrl *lvts_ctrl = container_of(lvts_sensor, struct lvts_ctrl,
  381. sensors[lvts_sensor->id]);
  382. const struct lvts_data *lvts_data = lvts_ctrl->lvts_data;
  383. void __iomem *base = lvts_sensor->base;
  384. u32 raw_low = lvts_temp_to_raw(low != -INT_MAX ? low : LVTS_MINIMUM_THRESHOLD,
  385. lvts_data);
  386. u32 raw_high = lvts_temp_to_raw(high, lvts_data);
  387. bool should_update_thresh;
  388. lvts_sensor->low_thresh = low;
  389. lvts_sensor->high_thresh = high;
  390. should_update_thresh = lvts_should_update_thresh(lvts_ctrl, high);
  391. if (should_update_thresh) {
  392. lvts_ctrl->high_thresh = high;
  393. lvts_ctrl->low_thresh = low;
  394. }
  395. lvts_update_irq_mask(lvts_ctrl);
  396. if (!should_update_thresh)
  397. return 0;
  398. /*
  399. * Low offset temperature threshold
  400. *
  401. * LVTS_OFFSETL
  402. *
  403. * Bits:
  404. *
  405. * 14-0 : Raw temperature for threshold
  406. */
  407. pr_debug("%s: Setting low limit temperature interrupt: %d\n",
  408. thermal_zone_device_type(tz), low);
  409. writel(raw_low, LVTS_OFFSETL(base));
  410. /*
  411. * High offset temperature threshold
  412. *
  413. * LVTS_OFFSETH
  414. *
  415. * Bits:
  416. *
  417. * 14-0 : Raw temperature for threshold
  418. */
  419. pr_debug("%s: Setting high limit temperature interrupt: %d\n",
  420. thermal_zone_device_type(tz), high);
  421. writel(raw_high, LVTS_OFFSETH(base));
  422. return 0;
  423. }
  424. static irqreturn_t lvts_ctrl_irq_handler(struct lvts_ctrl *lvts_ctrl)
  425. {
  426. irqreturn_t iret = IRQ_NONE;
  427. u32 value;
  428. static const u32 masks[] = {
  429. LVTS_INT_SENSOR0,
  430. LVTS_INT_SENSOR1,
  431. LVTS_INT_SENSOR2,
  432. LVTS_INT_SENSOR3
  433. };
  434. int i;
  435. /*
  436. * Interrupt monitoring status
  437. *
  438. * LVTS_MONINTST
  439. *
  440. * Bits:
  441. *
  442. * 31 : Interrupt for stage 3
  443. * 30 : Interrupt for stage 2
  444. * 29 : Interrupt for state 1
  445. * 28 : Interrupt using filter on sensor 3
  446. *
  447. * 27 : Interrupt using immediate on sensor 3
  448. * 26 : Interrupt normal to hot on sensor 3
  449. * 25 : Interrupt high offset on sensor 3
  450. * 24 : Interrupt low offset on sensor 3
  451. *
  452. * 23 : Interrupt hot threshold on sensor 3
  453. * 22 : Interrupt cold threshold on sensor 3
  454. * 21 : Interrupt using filter on sensor 2
  455. * 20 : Interrupt using filter on sensor 1
  456. *
  457. * 19 : Interrupt using filter on sensor 0
  458. * 18 : Interrupt using immediate on sensor 2
  459. * 17 : Interrupt using immediate on sensor 1
  460. * 16 : Interrupt using immediate on sensor 0
  461. *
  462. * 15 : Interrupt device access timeout interrupt
  463. * 14 : Interrupt normal to hot on sensor 2
  464. * 13 : Interrupt high offset interrupt on sensor 2
  465. * 12 : Interrupt low offset interrupt on sensor 2
  466. *
  467. * 11 : Interrupt hot threshold on sensor 2
  468. * 10 : Interrupt cold threshold on sensor 2
  469. * 9 : Interrupt normal to hot on sensor 1
  470. * 8 : Interrupt high offset interrupt on sensor 1
  471. *
  472. * 7 : Interrupt low offset interrupt on sensor 1
  473. * 6 : Interrupt hot threshold on sensor 1
  474. * 5 : Interrupt cold threshold on sensor 1
  475. * 4 : Interrupt normal to hot on sensor 0
  476. *
  477. * 3 : Interrupt high offset interrupt on sensor 0
  478. * 2 : Interrupt low offset interrupt on sensor 0
  479. * 1 : Interrupt hot threshold on sensor 0
  480. * 0 : Interrupt cold threshold on sensor 0
  481. *
  482. * We are interested in the sensor(s) responsible of the
  483. * interrupt event. We update the thermal framework with the
  484. * thermal zone associated with the sensor. The framework will
  485. * take care of the rest whatever the kind of interrupt, we
  486. * are only interested in which sensor raised the interrupt.
  487. *
  488. * sensor 3 interrupt: 0001 1111 1100 0000 0000 0000 0000 0000
  489. * => 0x1FC00000
  490. * sensor 2 interrupt: 0000 0000 0010 0100 0111 1100 0000 0000
  491. * => 0x00247C00
  492. * sensor 1 interrupt: 0000 0000 0001 0010 0000 0011 1110 0000
  493. * => 0X001203E0
  494. * sensor 0 interrupt: 0000 0000 0000 1001 0000 0000 0001 1111
  495. * => 0x0009001F
  496. */
  497. value = readl(LVTS_MONINTSTS(lvts_ctrl->base));
  498. /*
  499. * Let's figure out which sensors raised the interrupt
  500. *
  501. * NOTE: the masks array must be ordered with the index
  502. * corresponding to the sensor id eg. index=0, mask for
  503. * sensor0.
  504. */
  505. for (i = 0; i < ARRAY_SIZE(masks); i++) {
  506. if (!(value & masks[i]))
  507. continue;
  508. thermal_zone_device_update(lvts_ctrl->sensors[i].tz,
  509. THERMAL_TRIP_VIOLATED);
  510. iret = IRQ_HANDLED;
  511. }
  512. /*
  513. * Write back to clear the interrupt status (W1C)
  514. */
  515. writel(value, LVTS_MONINTSTS(lvts_ctrl->base));
  516. return iret;
  517. }
  518. /*
  519. * Temperature interrupt handler. Even if the driver supports more
  520. * interrupt modes, we use the interrupt when the temperature crosses
  521. * the hot threshold the way up and the way down (modulo the
  522. * hysteresis).
  523. *
  524. * Each thermal domain has a couple of interrupts, one for hardware
  525. * reset and another one for all the thermal events happening on the
  526. * different sensors.
  527. *
  528. * The interrupt is configured for thermal events when crossing the
  529. * hot temperature limit. At each interrupt, we check in every
  530. * controller if there is an interrupt pending.
  531. */
  532. static irqreturn_t lvts_irq_handler(int irq, void *data)
  533. {
  534. struct lvts_domain *lvts_td = data;
  535. irqreturn_t aux, iret = IRQ_NONE;
  536. int i;
  537. for (i = 0; i < lvts_td->num_lvts_ctrl; i++) {
  538. aux = lvts_ctrl_irq_handler(&lvts_td->lvts_ctrl[i]);
  539. if (aux != IRQ_HANDLED)
  540. continue;
  541. iret = IRQ_HANDLED;
  542. }
  543. return iret;
  544. }
  545. static const struct thermal_zone_device_ops lvts_ops = {
  546. .get_temp = lvts_get_temp,
  547. .set_trips = lvts_set_trips,
  548. };
  549. static int lvts_sensor_init(struct device *dev, struct lvts_ctrl *lvts_ctrl,
  550. const struct lvts_ctrl_data *lvts_ctrl_data)
  551. {
  552. struct lvts_sensor *lvts_sensor = lvts_ctrl->sensors;
  553. void __iomem *msr_regs[] = {
  554. LVTS_MSR0(lvts_ctrl->base),
  555. LVTS_MSR1(lvts_ctrl->base),
  556. LVTS_MSR2(lvts_ctrl->base),
  557. LVTS_MSR3(lvts_ctrl->base)
  558. };
  559. void __iomem *imm_regs[] = {
  560. LVTS_IMMD0(lvts_ctrl->base),
  561. LVTS_IMMD1(lvts_ctrl->base),
  562. LVTS_IMMD2(lvts_ctrl->base),
  563. LVTS_IMMD3(lvts_ctrl->base)
  564. };
  565. void __iomem *atp_regs[] = {
  566. LVTS_ATP0(lvts_ctrl->base),
  567. LVTS_ATP1(lvts_ctrl->base),
  568. LVTS_ATP2(lvts_ctrl->base),
  569. LVTS_ATP3(lvts_ctrl->base)
  570. };
  571. int i;
  572. lvts_for_each_valid_sensor(i, lvts_ctrl_data) {
  573. int dt_id = lvts_ctrl_data->lvts_sensor[i].dt_id;
  574. /*
  575. * At this point, we don't know which id matches which
  576. * sensor. Let's set arbitrally the id from the index.
  577. */
  578. lvts_sensor[i].id = i;
  579. /*
  580. * The thermal zone registration will set the trip
  581. * point interrupt in the thermal controller
  582. * register. But this one will be reset in the
  583. * initialization after. So we need to post pone the
  584. * thermal zone creation after the controller is
  585. * setup. For this reason, we store the device tree
  586. * node id from the data in the sensor structure
  587. */
  588. lvts_sensor[i].dt_id = dt_id;
  589. /*
  590. * We assign the base address of the thermal
  591. * controller as a back pointer. So it will be
  592. * accessible from the different thermal framework ops
  593. * as we pass the lvts_sensor pointer as thermal zone
  594. * private data.
  595. */
  596. lvts_sensor[i].base = lvts_ctrl->base;
  597. /*
  598. * Each sensor has its own register address to read from.
  599. */
  600. switch (lvts_ctrl_data->mode) {
  601. case LVTS_MSR_IMMEDIATE_MODE:
  602. lvts_sensor[i].msr = imm_regs[i];
  603. break;
  604. case LVTS_MSR_FILTERED_MODE:
  605. lvts_sensor[i].msr = msr_regs[i];
  606. break;
  607. case LVTS_MSR_ATP_MODE:
  608. lvts_sensor[i].msr = atp_regs[i];
  609. break;
  610. default:
  611. lvts_sensor[i].msr = imm_regs[i];
  612. break;
  613. }
  614. lvts_sensor[i].low_thresh = INT_MIN;
  615. lvts_sensor[i].high_thresh = INT_MIN;
  616. }
  617. lvts_ctrl->valid_sensor_mask = lvts_ctrl_data->valid_sensor_mask;
  618. return 0;
  619. }
  620. static int lvts_decode_sensor_calibration(const struct lvts_sensor_data *sensor,
  621. const u8 *efuse_calibration, u32 calib_len,
  622. u8 num_offsets, u32 *calib)
  623. {
  624. int i;
  625. u32 calib_val = 0;
  626. for (i = 0; i < num_offsets; i++) {
  627. u8 offset = sensor->cal_offsets[i];
  628. if (offset >= calib_len)
  629. return -EINVAL;
  630. // Pack each calibration byte into the correct position
  631. calib_val |= efuse_calibration[offset] << (8 * i);
  632. }
  633. *calib = calib_val;
  634. return 0;
  635. }
  636. /*
  637. * The efuse blob values follows the sensor enumeration per thermal
  638. * controller. The decoding of the stream is as follow:
  639. *
  640. * MT8192 :
  641. * Stream index map for MCU Domain mt8192 :
  642. *
  643. * <-----mcu-tc#0-----> <-----sensor#0-----> <-----sensor#1----->
  644. * 0x01 | 0x02 | 0x03 | 0x04 | 0x05 | 0x06 | 0x07 | 0x08 | 0x09 | 0x0A | 0x0B
  645. *
  646. * <-----sensor#2-----> <-----sensor#3----->
  647. * 0x0C | 0x0D | 0x0E | 0x0F | 0x10 | 0x11 | 0x12 | 0x13
  648. *
  649. * <-----sensor#4-----> <-----sensor#5-----> <-----sensor#6-----> <-----sensor#7----->
  650. * 0x14 | 0x15 | 0x16 | 0x17 | 0x18 | 0x19 | 0x1A | 0x1B | 0x1C | 0x1D | 0x1E | 0x1F | 0x20 | 0x21 | 0x22 | 0x23
  651. *
  652. * Stream index map for AP Domain mt8192 :
  653. *
  654. * <-----sensor#0-----> <-----sensor#1----->
  655. * 0x24 | 0x25 | 0x26 | 0x27 | 0x28 | 0x29 | 0x2A | 0x2B
  656. *
  657. * <-----sensor#2-----> <-----sensor#3----->
  658. * 0x2C | 0x2D | 0x2E | 0x2F | 0x30 | 0x31 | 0x32 | 0x33
  659. *
  660. * <-----sensor#4-----> <-----sensor#5----->
  661. * 0x34 | 0x35 | 0x36 | 0x37 | 0x38 | 0x39 | 0x3A | 0x3B
  662. *
  663. * <-----sensor#6-----> <-----sensor#7-----> <-----sensor#8----->
  664. * 0x3C | 0x3D | 0x3E | 0x3F | 0x40 | 0x41 | 0x42 | 0x43 | 0x44 | 0x45 | 0x46 | 0x47
  665. *
  666. * MT8195 :
  667. * Stream index map for MCU Domain mt8195 :
  668. *
  669. * <-----mcu-tc#0-----> <-----sensor#0-----> <-----sensor#1----->
  670. * 0x01 | 0x02 | 0x03 | 0x04 | 0x05 | 0x06 | 0x07 | 0x08 | 0x09
  671. *
  672. * <-----mcu-tc#1-----> <-----sensor#2-----> <-----sensor#3----->
  673. * 0x0A | 0x0B | 0x0C | 0x0D | 0x0E | 0x0F | 0x10 | 0x11 | 0x12
  674. *
  675. * <-----mcu-tc#2-----> <-----sensor#4-----> <-----sensor#5-----> <-----sensor#6-----> <-----sensor#7----->
  676. * 0x13 | 0x14 | 0x15 | 0x16 | 0x17 | 0x18 | 0x19 | 0x1A | 0x1B | 0x1C | 0x1D | 0x1E | 0x1F | 0x20 | 0x21
  677. *
  678. * Stream index map for AP Domain mt8195 :
  679. *
  680. * <-----ap--tc#0-----> <-----sensor#0-----> <-----sensor#1----->
  681. * 0x22 | 0x23 | 0x24 | 0x25 | 0x26 | 0x27 | 0x28 | 0x29 | 0x2A
  682. *
  683. * <-----ap--tc#1-----> <-----sensor#2-----> <-----sensor#3----->
  684. * 0x2B | 0x2C | 0x2D | 0x2E | 0x2F | 0x30 | 0x31 | 0x32 | 0x33
  685. *
  686. * <-----ap--tc#2-----> <-----sensor#4-----> <-----sensor#5-----> <-----sensor#6----->
  687. * 0x34 | 0x35 | 0x36 | 0x37 | 0x38 | 0x39 | 0x3A | 0x3B | 0x3C | 0x3D | 0x3E | 0x3F
  688. *
  689. * <-----ap--tc#3-----> <-----sensor#7-----> <-----sensor#8----->
  690. * 0x40 | 0x41 | 0x42 | 0x43 | 0x44 | 0x45 | 0x46 | 0x47 | 0x48
  691. *
  692. * MT8196 :
  693. * Stream index map for MCU Domain mt8196 :
  694. *
  695. * <-sensor#1--> <-sensor#0--> <-sensor#3--> <-sensor#2-->
  696. * 0x04 | 0x05 | 0x06 | 0x07 | 0x08 | 0x09 | 0x0A | 0x0B
  697. *
  698. * <-sensor#5--> <-sensor#4--> <-sensor#7--> <-sensor#6-->
  699. * 0x0C | 0x0D | 0x0E | 0x0F | 0x10 | 0x11 | 0x12 | 0x13
  700. *
  701. * <-sensor#9--> <-sensor#8--> <-sensor#11-> <-sensor#10->
  702. * 0x14 | 0x15 | 0x16 | 0x17 | 0x18 | 0x19 | 0x1A | 0X1B
  703. *
  704. * <-sensor#13-> <-sensor#12-> <-sensor#15-> <-sensor#14->
  705. * 0x1C | 0x1D | 0x1E | 0x1F | 0x20 | 0x21 | 0x22 | 0x23
  706. *
  707. * Stream index map for APU Domain mt8196 :
  708. *
  709. * <-sensor#1--> <-sensor#0--> <-sensor#3--> <-sensor#2-->
  710. * 0x24 | 0x25 | 0x26 | 0x27 | 0x28 | 0x29 | 0x2A | 0x2B
  711. *
  712. * Stream index map for GPU Domain mt8196 :
  713. *
  714. * <-sensor#1--> <-sensor#0-->
  715. * 0x2C | 0x2D | 0x2E | 0x2F
  716. *
  717. * Stream index map for AP Domain mt8196 :
  718. *
  719. * <-sensor#1--> <-sensor#0--> <-sensor#3--> <-sensor#2-->
  720. * 0x30 | 0x31 | 0x32 | 0x33 | 0x34 | 0x35 | 0x36 | 0x37
  721. *
  722. * <-sensor#5--> <-sensor#4--> <-sensor#6--> <-sensor#7-->
  723. * 0x38 | 0x39 | 0x3A | 0x3B | 0x3C | 0x3D | 0x3E | 0x3F
  724. *
  725. * Note: In some cases, values don't strictly follow a little endian ordering.
  726. * The data description gives byte offsets constituting each calibration value
  727. * for each sensor.
  728. */
  729. static int lvts_calibration_init(struct device *dev, struct lvts_ctrl *lvts_ctrl,
  730. const struct lvts_ctrl_data *lvts_ctrl_data,
  731. u8 *efuse_calibration,
  732. size_t calib_len)
  733. {
  734. const struct lvts_data *lvts_data = lvts_ctrl->lvts_data;
  735. int i, ret;
  736. u32 gt;
  737. /* A zero value for gt means that device has invalid efuse data */
  738. gt = (((u32 *)efuse_calibration)[0] >> lvts_data->gt_calib_bit_offset) & 0xff;
  739. lvts_for_each_valid_sensor(i, lvts_ctrl_data) {
  740. const struct lvts_sensor_data *sensor =
  741. &lvts_ctrl_data->lvts_sensor[i];
  742. u32 calib = 0;
  743. ret = lvts_decode_sensor_calibration(sensor, efuse_calibration,
  744. calib_len,
  745. lvts_data->num_cal_offsets,
  746. &calib);
  747. if (ret)
  748. return ret;
  749. if (gt) {
  750. lvts_ctrl->calibration[i] = calib;
  751. if (lvts_ctrl->lvts_data->msr_offset)
  752. lvts_ctrl->calibration[i] += lvts_ctrl->lvts_data->msr_offset;
  753. } else if (lvts_ctrl->lvts_data->def_calibration) {
  754. lvts_ctrl->calibration[i] = lvts_ctrl->lvts_data->def_calibration;
  755. } else {
  756. dev_err(dev, "efuse contains invalid calibration data and no default given.\n");
  757. return -ENODATA;
  758. }
  759. }
  760. return 0;
  761. }
  762. /*
  763. * The efuse bytes stream can be split into different chunk of
  764. * nvmems. This function reads and concatenate those into a single
  765. * buffer so it can be read sequentially when initializing the
  766. * calibration data.
  767. */
  768. static int lvts_calibration_read(struct device *dev, struct lvts_domain *lvts_td,
  769. const struct lvts_data *lvts_data)
  770. {
  771. struct device_node *np = dev_of_node(dev);
  772. struct nvmem_cell *cell;
  773. struct property *prop;
  774. const char *cell_name;
  775. of_property_for_each_string(np, "nvmem-cell-names", prop, cell_name) {
  776. size_t len;
  777. u8 *efuse;
  778. cell = of_nvmem_cell_get(np, cell_name);
  779. if (IS_ERR(cell)) {
  780. dev_err(dev, "Failed to get cell '%s'\n", cell_name);
  781. return PTR_ERR(cell);
  782. }
  783. efuse = nvmem_cell_read(cell, &len);
  784. nvmem_cell_put(cell);
  785. if (IS_ERR(efuse)) {
  786. dev_err(dev, "Failed to read cell '%s'\n", cell_name);
  787. return PTR_ERR(efuse);
  788. }
  789. lvts_td->calib = devm_krealloc(dev, lvts_td->calib,
  790. lvts_td->calib_len + len, GFP_KERNEL);
  791. if (!lvts_td->calib) {
  792. kfree(efuse);
  793. return -ENOMEM;
  794. }
  795. memcpy(lvts_td->calib + lvts_td->calib_len, efuse, len);
  796. lvts_td->calib_len += len;
  797. kfree(efuse);
  798. }
  799. return 0;
  800. }
  801. static int lvts_golden_temp_init(struct device *dev, u8 *calib,
  802. const struct lvts_data *lvts_data)
  803. {
  804. u32 gt;
  805. /*
  806. * The golden temp information is contained in the first 32-bit
  807. * word of efuse data at a specific bit offset.
  808. */
  809. gt = (((u32 *)calib)[0] >> lvts_data->gt_calib_bit_offset) & 0xff;
  810. /* A zero value for gt means that device has invalid efuse data */
  811. if (gt && gt < LVTS_GOLDEN_TEMP_MAX)
  812. golden_temp = gt;
  813. golden_temp_offset = golden_temp * 500 + lvts_data->temp_offset;
  814. dev_info(dev, "%sgolden temp=%d\n", gt ? "" : "fake ", golden_temp);
  815. return 0;
  816. }
  817. static int lvts_ctrl_init(struct device *dev, struct lvts_domain *lvts_td,
  818. const struct lvts_data *lvts_data)
  819. {
  820. size_t size = sizeof(*lvts_td->lvts_ctrl) * lvts_data->num_lvts_ctrl;
  821. struct lvts_ctrl *lvts_ctrl;
  822. int i, ret;
  823. /*
  824. * Create the calibration bytes stream from efuse data
  825. */
  826. ret = lvts_calibration_read(dev, lvts_td, lvts_data);
  827. if (ret)
  828. return ret;
  829. ret = lvts_golden_temp_init(dev, lvts_td->calib, lvts_data);
  830. if (ret)
  831. return ret;
  832. lvts_ctrl = devm_kzalloc(dev, size, GFP_KERNEL);
  833. if (!lvts_ctrl)
  834. return -ENOMEM;
  835. for (i = 0; i < lvts_data->num_lvts_ctrl; i++) {
  836. lvts_ctrl[i].base = lvts_td->base + lvts_data->lvts_ctrl[i].offset;
  837. lvts_ctrl[i].lvts_data = lvts_data;
  838. ret = lvts_sensor_init(dev, &lvts_ctrl[i],
  839. &lvts_data->lvts_ctrl[i]);
  840. if (ret)
  841. return ret;
  842. ret = lvts_calibration_init(dev, &lvts_ctrl[i],
  843. &lvts_data->lvts_ctrl[i],
  844. lvts_td->calib,
  845. lvts_td->calib_len);
  846. if (ret)
  847. return ret;
  848. /*
  849. * The mode the ctrl will use to read the temperature
  850. * (filtered or immediate)
  851. */
  852. lvts_ctrl[i].mode = lvts_data->lvts_ctrl[i].mode;
  853. lvts_ctrl[i].low_thresh = INT_MIN;
  854. lvts_ctrl[i].high_thresh = INT_MIN;
  855. }
  856. /*
  857. * We no longer need the efuse bytes stream, let's free it
  858. */
  859. devm_kfree(dev, lvts_td->calib);
  860. lvts_td->lvts_ctrl = lvts_ctrl;
  861. lvts_td->num_lvts_ctrl = lvts_data->num_lvts_ctrl;
  862. return 0;
  863. }
  864. static void lvts_ctrl_monitor_enable(struct device *dev, struct lvts_ctrl *lvts_ctrl, bool enable)
  865. {
  866. /*
  867. * Bitmaps to enable each sensor on filtered mode in the MONCTL0
  868. * register.
  869. */
  870. static const u8 sensor_filt_bitmap[] = { BIT(0), BIT(1), BIT(2), BIT(3) };
  871. u32 sensor_map = 0;
  872. int i;
  873. if (lvts_ctrl->mode == LVTS_MSR_IMMEDIATE_MODE)
  874. return;
  875. if (enable) {
  876. lvts_for_each_valid_sensor(i, lvts_ctrl)
  877. sensor_map |= sensor_filt_bitmap[i];
  878. }
  879. /*
  880. * Bits:
  881. * 9: Single point access flow
  882. * 0-3: Enable sensing point 0-3
  883. */
  884. writel(sensor_map | BIT(9), LVTS_MONCTL0(lvts_ctrl->base));
  885. }
  886. /*
  887. * At this point the configuration register is the only place in the
  888. * driver where we write multiple values. Per hardware constraint,
  889. * each write in the configuration register must be separated by a
  890. * delay of 2 us.
  891. */
  892. static void lvts_write_config(struct lvts_ctrl *lvts_ctrl, const u32 *cmds, int nr_cmds)
  893. {
  894. int i;
  895. /*
  896. * Configuration register
  897. */
  898. for (i = 0; i < nr_cmds; i++) {
  899. writel(cmds[i], LVTS_CONFIG(lvts_ctrl->base));
  900. usleep_range(2, 4);
  901. }
  902. }
  903. static int lvts_irq_init(struct lvts_ctrl *lvts_ctrl)
  904. {
  905. /*
  906. * LVTS_PROTCTL : Thermal Protection Sensor Selection
  907. *
  908. * Bits:
  909. *
  910. * 19-18 : Sensor to base the protection on
  911. * 17-16 : Strategy:
  912. * 00 : Average of 4 sensors
  913. * 01 : Max of 4 sensors
  914. * 10 : Selected sensor with bits 19-18
  915. * 11 : Reserved
  916. */
  917. /*
  918. * LVTS_PROTTA : Stage 1 temperature threshold
  919. * LVTS_PROTTB : Stage 2 temperature threshold
  920. * LVTS_PROTTC : Stage 3 temperature threshold
  921. *
  922. * Bits:
  923. *
  924. * 14-0: Raw temperature threshold
  925. *
  926. * writel(0x0, LVTS_PROTTA(lvts_ctrl->base));
  927. * writel(0x0, LVTS_PROTTB(lvts_ctrl->base));
  928. * writel(0x0, LVTS_PROTTC(lvts_ctrl->base));
  929. */
  930. /*
  931. * LVTS_MONINT : Interrupt configuration register
  932. *
  933. * The LVTS_MONINT register layout is the same as the LVTS_MONINTSTS
  934. * register, except we set the bits to enable the interrupt.
  935. */
  936. writel(0, LVTS_MONINT(lvts_ctrl->base));
  937. return 0;
  938. }
  939. static int lvts_domain_reset(struct device *dev, struct reset_control *reset)
  940. {
  941. int ret;
  942. ret = reset_control_assert(reset);
  943. if (ret)
  944. return ret;
  945. return reset_control_deassert(reset);
  946. }
  947. /*
  948. * Enable or disable the clocks of a specified thermal controller
  949. */
  950. static int lvts_ctrl_set_enable(struct lvts_ctrl *lvts_ctrl, int enable)
  951. {
  952. /*
  953. * LVTS_CLKEN : Internal LVTS clock
  954. *
  955. * Bits:
  956. *
  957. * 0 : enable / disable clock
  958. */
  959. writel(enable, LVTS_CLKEN(lvts_ctrl->base));
  960. return 0;
  961. }
  962. static int lvts_ctrl_connect(struct device *dev, struct lvts_ctrl *lvts_ctrl)
  963. {
  964. const struct lvts_data *lvts_data = lvts_ctrl->lvts_data;
  965. u32 id;
  966. lvts_write_config(lvts_ctrl, lvts_data->conn_cmd, lvts_data->num_conn_cmd);
  967. /*
  968. * LVTS_ID : Get ID and status of the thermal controller
  969. *
  970. * Bits:
  971. *
  972. * 0-5 : thermal controller id
  973. * 7 : thermal controller connection is valid
  974. */
  975. id = readl(LVTS_ID(lvts_ctrl->base));
  976. if (!(id & BIT(7)))
  977. return -EIO;
  978. return 0;
  979. }
  980. static int lvts_ctrl_initialize(struct device *dev, struct lvts_ctrl *lvts_ctrl)
  981. {
  982. const struct lvts_data *lvts_data = lvts_ctrl->lvts_data;
  983. lvts_write_config(lvts_ctrl, lvts_data->init_cmd, lvts_data->num_init_cmd);
  984. return 0;
  985. }
  986. static int lvts_ctrl_calibrate(struct device *dev, struct lvts_ctrl *lvts_ctrl)
  987. {
  988. int i;
  989. void __iomem *lvts_edata[] = {
  990. LVTS_EDATA00(lvts_ctrl->base),
  991. LVTS_EDATA01(lvts_ctrl->base),
  992. LVTS_EDATA02(lvts_ctrl->base),
  993. LVTS_EDATA03(lvts_ctrl->base)
  994. };
  995. /*
  996. * LVTS_EDATA0X : Efuse calibration reference value for sensor X
  997. *
  998. * Bits:
  999. *
  1000. * 20-0 : Efuse value for normalization data
  1001. */
  1002. for (i = 0; i < LVTS_SENSOR_MAX; i++)
  1003. writel(lvts_ctrl->calibration[i], lvts_edata[i]);
  1004. /* LVTS_MSROFT : Constant offset applied to MSR values
  1005. * for post-processing
  1006. *
  1007. * Bits:
  1008. *
  1009. * 20-0 : Constant data added to MSR values
  1010. */
  1011. if (lvts_ctrl->lvts_data->msr_offset)
  1012. writel(lvts_ctrl->lvts_data->msr_offset,
  1013. LVTS_MSROFT(lvts_ctrl->base));
  1014. return 0;
  1015. }
  1016. static int lvts_ctrl_configure(struct device *dev, struct lvts_ctrl *lvts_ctrl)
  1017. {
  1018. u32 value;
  1019. /*
  1020. * LVTS_TSSEL : Sensing point index numbering
  1021. *
  1022. * Bits:
  1023. *
  1024. * 31-24: ADC Sense 3
  1025. * 23-16: ADC Sense 2
  1026. * 15-8 : ADC Sense 1
  1027. * 7-0 : ADC Sense 0
  1028. */
  1029. value = LVTS_TSSEL_CONF;
  1030. writel(value, LVTS_TSSEL(lvts_ctrl->base));
  1031. /*
  1032. * LVTS_CALSCALE : ADC voltage round
  1033. */
  1034. value = 0x300;
  1035. value = LVTS_CALSCALE_CONF;
  1036. /*
  1037. * LVTS_MSRCTL0 : Sensor filtering strategy
  1038. *
  1039. * Filters:
  1040. *
  1041. * 000 : One sample
  1042. * 001 : Avg 2 samples
  1043. * 010 : 4 samples, drop min and max, avg 2 samples
  1044. * 011 : 6 samples, drop min and max, avg 4 samples
  1045. * 100 : 10 samples, drop min and max, avg 8 samples
  1046. * 101 : 18 samples, drop min and max, avg 16 samples
  1047. *
  1048. * Bits:
  1049. *
  1050. * 0-2 : Sensor0 filter
  1051. * 3-5 : Sensor1 filter
  1052. * 6-8 : Sensor2 filter
  1053. * 9-11 : Sensor3 filter
  1054. */
  1055. value = LVTS_HW_FILTER << 9 | LVTS_HW_FILTER << 6 |
  1056. LVTS_HW_FILTER << 3 | LVTS_HW_FILTER;
  1057. writel(value, LVTS_MSRCTL0(lvts_ctrl->base));
  1058. /*
  1059. * LVTS_MONCTL1 : Period unit and group interval configuration
  1060. *
  1061. * The clock source of LVTS thermal controller is 26MHz.
  1062. *
  1063. * The period unit is a time base for all the interval delays
  1064. * specified in the registers. By default we use 12. The time
  1065. * conversion is done by multiplying by 256 and 1/26.10^6
  1066. *
  1067. * An interval delay multiplied by the period unit gives the
  1068. * duration in seconds.
  1069. *
  1070. * - Filter interval delay is a delay between two samples of
  1071. * the same sensor.
  1072. *
  1073. * - Sensor interval delay is a delay between two samples of
  1074. * different sensors.
  1075. *
  1076. * - Group interval delay is a delay between different rounds.
  1077. *
  1078. * For example:
  1079. * If Period unit = C, filter delay = 1, sensor delay = 2, group delay = 1,
  1080. * and two sensors, TS1 and TS2, are in a LVTS thermal controller
  1081. * and then
  1082. * Period unit time = C * 1/26M * 256 = 12 * 38.46ns * 256 = 118.149us
  1083. * Filter interval delay = 1 * Period unit = 118.149us
  1084. * Sensor interval delay = 2 * Period unit = 236.298us
  1085. * Group interval delay = 1 * Period unit = 118.149us
  1086. *
  1087. * TS1 TS1 ... TS1 TS2 TS2 ... TS2 TS1...
  1088. * <--> Filter interval delay
  1089. * <--> Sensor interval delay
  1090. * <--> Group interval delay
  1091. * Bits:
  1092. * 29 - 20 : Group interval
  1093. * 16 - 13 : Send a single interrupt when crossing the hot threshold (1)
  1094. * or an interrupt everytime the hot threshold is crossed (0)
  1095. * 9 - 0 : Period unit
  1096. *
  1097. */
  1098. value = LVTS_GROUP_INTERVAL << 20 | LVTS_PERIOD_UNIT;
  1099. writel(value, LVTS_MONCTL1(lvts_ctrl->base));
  1100. /*
  1101. * LVTS_MONCTL2 : Filtering and sensor interval
  1102. *
  1103. * Bits:
  1104. *
  1105. * 25-16 : Interval unit in PERIOD_UNIT between sample on
  1106. * the same sensor, filter interval
  1107. * 9-0 : Interval unit in PERIOD_UNIT between each sensor
  1108. *
  1109. */
  1110. value = LVTS_FILTER_INTERVAL << 16 | LVTS_SENSOR_INTERVAL;
  1111. writel(value, LVTS_MONCTL2(lvts_ctrl->base));
  1112. return lvts_irq_init(lvts_ctrl);
  1113. }
  1114. static int lvts_ctrl_start(struct device *dev, struct lvts_ctrl *lvts_ctrl)
  1115. {
  1116. struct lvts_sensor *lvts_sensors = lvts_ctrl->sensors;
  1117. struct thermal_zone_device *tz;
  1118. u32 sensor_map = 0;
  1119. int i;
  1120. /*
  1121. * Bitmaps to enable each sensor on immediate and filtered modes, as
  1122. * described in MSRCTL1 and MONCTL0 registers below, respectively.
  1123. */
  1124. u32 sensor_imm_bitmap[] = { BIT(4), BIT(5), BIT(6), BIT(9) };
  1125. u32 sensor_filt_bitmap[] = { BIT(0), BIT(1), BIT(2), BIT(3) };
  1126. u32 *sensor_bitmap = lvts_ctrl->mode == LVTS_MSR_IMMEDIATE_MODE ?
  1127. sensor_imm_bitmap : sensor_filt_bitmap;
  1128. lvts_for_each_valid_sensor(i, lvts_ctrl) {
  1129. int dt_id = lvts_sensors[i].dt_id;
  1130. tz = devm_thermal_of_zone_register(dev, dt_id, &lvts_sensors[i],
  1131. &lvts_ops);
  1132. if (IS_ERR(tz)) {
  1133. /*
  1134. * This thermal zone is not described in the
  1135. * device tree. It is not an error from the
  1136. * thermal OF code POV, we just continue.
  1137. */
  1138. if (PTR_ERR(tz) == -ENODEV)
  1139. continue;
  1140. return PTR_ERR(tz);
  1141. }
  1142. devm_thermal_add_hwmon_sysfs(dev, tz);
  1143. /*
  1144. * The thermal zone pointer will be needed in the
  1145. * interrupt handler, we store it in the sensor
  1146. * structure. The thermal domain structure will be
  1147. * passed to the interrupt handler private data as the
  1148. * interrupt is shared for all the controller
  1149. * belonging to the thermal domain.
  1150. */
  1151. lvts_sensors[i].tz = tz;
  1152. /*
  1153. * This sensor was correctly associated with a thermal
  1154. * zone, let's set the corresponding bit in the sensor
  1155. * map, so we can enable the temperature monitoring in
  1156. * the hardware thermal controller.
  1157. */
  1158. sensor_map |= sensor_bitmap[i];
  1159. }
  1160. /*
  1161. * The initialization of the thermal zones give us
  1162. * which sensor point to enable. If any thermal zone
  1163. * was not described in the device tree, it won't be
  1164. * enabled here in the sensor map.
  1165. */
  1166. if (lvts_ctrl->mode == LVTS_MSR_IMMEDIATE_MODE) {
  1167. /*
  1168. * LVTS_MSRCTL1 : Measurement control
  1169. *
  1170. * Bits:
  1171. *
  1172. * 9: Ignore MSRCTL0 config and do immediate measurement on sensor3
  1173. * 6: Ignore MSRCTL0 config and do immediate measurement on sensor2
  1174. * 5: Ignore MSRCTL0 config and do immediate measurement on sensor1
  1175. * 4: Ignore MSRCTL0 config and do immediate measurement on sensor0
  1176. *
  1177. * That configuration will ignore the filtering and the delays
  1178. * introduced in MONCTL1 and MONCTL2
  1179. */
  1180. writel(sensor_map, LVTS_MSRCTL1(lvts_ctrl->base));
  1181. } else {
  1182. /*
  1183. * Bits:
  1184. * 9: Single point access flow
  1185. * 0-3: Enable sensing point 0-3
  1186. */
  1187. writel(sensor_map | BIT(9), LVTS_MONCTL0(lvts_ctrl->base));
  1188. }
  1189. return 0;
  1190. }
  1191. static int lvts_domain_init(struct device *dev, struct lvts_domain *lvts_td,
  1192. const struct lvts_data *lvts_data)
  1193. {
  1194. struct lvts_ctrl *lvts_ctrl;
  1195. int i, ret;
  1196. ret = lvts_ctrl_init(dev, lvts_td, lvts_data);
  1197. if (ret)
  1198. return ret;
  1199. ret = lvts_domain_reset(dev, lvts_td->reset);
  1200. if (ret) {
  1201. dev_dbg(dev, "Failed to reset domain");
  1202. return ret;
  1203. }
  1204. for (i = 0; i < lvts_td->num_lvts_ctrl; i++) {
  1205. lvts_ctrl = &lvts_td->lvts_ctrl[i];
  1206. /*
  1207. * Initialization steps:
  1208. *
  1209. * - Enable the clock
  1210. * - Connect to the LVTS
  1211. * - Initialize the LVTS
  1212. * - Prepare the calibration data
  1213. * - Select monitored sensors
  1214. * [ Configure sampling ]
  1215. * [ Configure the interrupt ]
  1216. * - Start measurement
  1217. */
  1218. ret = lvts_ctrl_set_enable(lvts_ctrl, true);
  1219. if (ret) {
  1220. dev_dbg(dev, "Failed to enable LVTS clock");
  1221. return ret;
  1222. }
  1223. ret = lvts_ctrl_connect(dev, lvts_ctrl);
  1224. if (ret) {
  1225. dev_dbg(dev, "Failed to connect to LVTS controller");
  1226. return ret;
  1227. }
  1228. ret = lvts_ctrl_initialize(dev, lvts_ctrl);
  1229. if (ret) {
  1230. dev_dbg(dev, "Failed to initialize controller");
  1231. return ret;
  1232. }
  1233. ret = lvts_ctrl_calibrate(dev, lvts_ctrl);
  1234. if (ret) {
  1235. dev_dbg(dev, "Failed to calibrate controller");
  1236. return ret;
  1237. }
  1238. ret = lvts_ctrl_configure(dev, lvts_ctrl);
  1239. if (ret) {
  1240. dev_dbg(dev, "Failed to configure controller");
  1241. return ret;
  1242. }
  1243. ret = lvts_ctrl_start(dev, lvts_ctrl);
  1244. if (ret) {
  1245. dev_dbg(dev, "Failed to start controller");
  1246. return ret;
  1247. }
  1248. }
  1249. return lvts_debugfs_init(dev, lvts_td);
  1250. }
  1251. static int lvts_probe(struct platform_device *pdev)
  1252. {
  1253. const struct lvts_data *lvts_data;
  1254. struct lvts_domain *lvts_td;
  1255. struct device *dev = &pdev->dev;
  1256. struct resource *res;
  1257. int irq, ret;
  1258. lvts_td = devm_kzalloc(dev, sizeof(*lvts_td), GFP_KERNEL);
  1259. if (!lvts_td)
  1260. return -ENOMEM;
  1261. lvts_data = of_device_get_match_data(dev);
  1262. if (!lvts_data)
  1263. return -ENODEV;
  1264. lvts_td->clk = devm_clk_get_enabled(dev, NULL);
  1265. if (IS_ERR(lvts_td->clk))
  1266. return dev_err_probe(dev, PTR_ERR(lvts_td->clk), "Failed to retrieve clock\n");
  1267. res = platform_get_mem_or_io(pdev, 0);
  1268. if (!res)
  1269. return dev_err_probe(dev, (-ENXIO), "No IO resource\n");
  1270. lvts_td->base = devm_platform_get_and_ioremap_resource(pdev, 0, &res);
  1271. if (IS_ERR(lvts_td->base))
  1272. return dev_err_probe(dev, PTR_ERR(lvts_td->base), "Failed to map io resource\n");
  1273. lvts_td->reset = devm_reset_control_get_by_index(dev, 0);
  1274. if (IS_ERR(lvts_td->reset))
  1275. return dev_err_probe(dev, PTR_ERR(lvts_td->reset), "Failed to get reset control\n");
  1276. irq = platform_get_irq(pdev, 0);
  1277. if (irq < 0)
  1278. return irq;
  1279. golden_temp_offset = lvts_data->temp_offset;
  1280. ret = lvts_domain_init(dev, lvts_td, lvts_data);
  1281. if (ret)
  1282. return dev_err_probe(dev, ret, "Failed to initialize the lvts domain\n");
  1283. /*
  1284. * At this point the LVTS is initialized and enabled. We can
  1285. * safely enable the interrupt.
  1286. */
  1287. ret = devm_request_threaded_irq(dev, irq, NULL, lvts_irq_handler,
  1288. IRQF_ONESHOT, dev_name(dev), lvts_td);
  1289. if (ret)
  1290. return dev_err_probe(dev, ret, "Failed to request interrupt\n");
  1291. platform_set_drvdata(pdev, lvts_td);
  1292. return 0;
  1293. }
  1294. static void lvts_remove(struct platform_device *pdev)
  1295. {
  1296. struct lvts_domain *lvts_td;
  1297. int i;
  1298. lvts_td = platform_get_drvdata(pdev);
  1299. for (i = 0; i < lvts_td->num_lvts_ctrl; i++)
  1300. lvts_ctrl_set_enable(&lvts_td->lvts_ctrl[i], false);
  1301. }
  1302. static const struct lvts_ctrl_data mt7987_lvts_ap_data_ctrl[] = {
  1303. {
  1304. .lvts_sensor = {
  1305. { .dt_id = MT7987_CPU,
  1306. .cal_offsets = { 0x04, 0x05, 0x06 } },
  1307. { .dt_id = MT7987_ETH2P5G,
  1308. .cal_offsets = { 0x08, 0x09, 0x0a } },
  1309. },
  1310. VALID_SENSOR_MAP(1, 1, 0, 0),
  1311. .offset = 0x0,
  1312. .mode = LVTS_MSR_FILTERED_MODE,
  1313. },
  1314. };
  1315. static const struct lvts_ctrl_data mt7988_lvts_ap_data_ctrl[] = {
  1316. {
  1317. .lvts_sensor = {
  1318. { .dt_id = MT7988_CPU_0,
  1319. .cal_offsets = { 0x00, 0x01, 0x02 } },
  1320. { .dt_id = MT7988_CPU_1,
  1321. .cal_offsets = { 0x04, 0x05, 0x06 } },
  1322. { .dt_id = MT7988_ETH2P5G_0,
  1323. .cal_offsets = { 0x08, 0x09, 0x0a } },
  1324. { .dt_id = MT7988_ETH2P5G_1,
  1325. .cal_offsets = { 0x0c, 0x0d, 0x0e } }
  1326. },
  1327. VALID_SENSOR_MAP(1, 1, 1, 1),
  1328. .offset = 0x0,
  1329. },
  1330. {
  1331. .lvts_sensor = {
  1332. { .dt_id = MT7988_TOPS_0,
  1333. .cal_offsets = { 0x14, 0x15, 0x16 } },
  1334. { .dt_id = MT7988_TOPS_1,
  1335. .cal_offsets = { 0x18, 0x19, 0x1a } },
  1336. { .dt_id = MT7988_ETHWARP_0,
  1337. .cal_offsets = { 0x1c, 0x1d, 0x1e } },
  1338. { .dt_id = MT7988_ETHWARP_1,
  1339. .cal_offsets = { 0x20, 0x21, 0x22 } }
  1340. },
  1341. VALID_SENSOR_MAP(1, 1, 1, 1),
  1342. .offset = 0x100,
  1343. }
  1344. };
  1345. static int lvts_suspend(struct device *dev)
  1346. {
  1347. struct lvts_domain *lvts_td;
  1348. int i;
  1349. lvts_td = dev_get_drvdata(dev);
  1350. for (i = 0; i < lvts_td->num_lvts_ctrl; i++) {
  1351. lvts_ctrl_monitor_enable(dev, &lvts_td->lvts_ctrl[i], false);
  1352. usleep_range(100, 200);
  1353. lvts_ctrl_set_enable(&lvts_td->lvts_ctrl[i], false);
  1354. }
  1355. clk_disable_unprepare(lvts_td->clk);
  1356. return 0;
  1357. }
  1358. static int lvts_resume(struct device *dev)
  1359. {
  1360. struct lvts_domain *lvts_td;
  1361. int i, ret;
  1362. lvts_td = dev_get_drvdata(dev);
  1363. ret = clk_prepare_enable(lvts_td->clk);
  1364. if (ret)
  1365. return ret;
  1366. for (i = 0; i < lvts_td->num_lvts_ctrl; i++) {
  1367. lvts_ctrl_set_enable(&lvts_td->lvts_ctrl[i], true);
  1368. usleep_range(100, 200);
  1369. lvts_ctrl_monitor_enable(dev, &lvts_td->lvts_ctrl[i], true);
  1370. }
  1371. return 0;
  1372. }
  1373. static const u32 default_conn_cmds[] = { 0xC103FFFF, 0xC502FF55 };
  1374. static const u32 mt7988_conn_cmds[] = { 0xC103FFFF, 0xC502FC55 };
  1375. /*
  1376. * Write device mask: 0xC1030000
  1377. */
  1378. static const u32 default_init_cmds[] = {
  1379. 0xC1030E01, 0xC1030CFC, 0xC1030A8C, 0xC103098D, 0xC10308F1,
  1380. 0xC10307A6, 0xC10306B8, 0xC1030500, 0xC1030420, 0xC1030300,
  1381. 0xC1030030, 0xC10300F6, 0xC1030050, 0xC1030060, 0xC10300AC,
  1382. 0xC10300FC, 0xC103009D, 0xC10300F1, 0xC10300E1
  1383. };
  1384. static const u32 mt7987_init_cmds[] = {
  1385. 0xC1030300, 0xC1030420, 0xC1030500, 0xC10307A6, 0xC10308C7,
  1386. 0xC103098D, 0xC1030C7C, 0xC1030AA8, 0xC10308CE, 0xC10308C7,
  1387. 0xC1030B04, 0xC1030E01, 0xC10306B8
  1388. };
  1389. static const u32 mt7988_init_cmds[] = {
  1390. 0xC1030300, 0xC1030420, 0xC1030500, 0xC10307A6, 0xC1030CFC,
  1391. 0xC1030A8C, 0xC103098D, 0xC10308F1, 0xC1030B04, 0xC1030E01,
  1392. 0xC10306B8
  1393. };
  1394. /*
  1395. * The MT8186 calibration data is stored as packed 3-byte little-endian
  1396. * values using a weird layout that makes sense only when viewed as a 32-bit
  1397. * hexadecimal word dump. Let's suppose SxBy where x = sensor number and
  1398. * y = byte number where the LSB is y=0. We then have:
  1399. *
  1400. * [S0B2-S0B1-S0B0-S1B2] [S1B1-S1B0-S2B2-S2B1] [S2B0-S3B2-S3B1-S3B0]
  1401. *
  1402. * However, when considering a byte stream, those appear as follows:
  1403. *
  1404. * [S1B2] [S0B0[ [S0B1] [S0B2] [S2B1] [S2B2] [S1B0] [S1B1] [S3B0] [S3B1] [S3B2] [S2B0]
  1405. *
  1406. * Hence the rather confusing offsets provided below.
  1407. */
  1408. static const struct lvts_ctrl_data mt8186_lvts_data_ctrl[] = {
  1409. {
  1410. .lvts_sensor = {
  1411. { .dt_id = MT8186_LITTLE_CPU0,
  1412. .cal_offsets = { 5, 6, 7 } },
  1413. { .dt_id = MT8186_LITTLE_CPU1,
  1414. .cal_offsets = { 10, 11, 4 } },
  1415. { .dt_id = MT8186_LITTLE_CPU2,
  1416. .cal_offsets = { 15, 8, 9 } },
  1417. { .dt_id = MT8186_CAM,
  1418. .cal_offsets = { 12, 13, 14 } }
  1419. },
  1420. VALID_SENSOR_MAP(1, 1, 1, 1),
  1421. .offset = 0x0,
  1422. },
  1423. {
  1424. .lvts_sensor = {
  1425. { .dt_id = MT8186_BIG_CPU0,
  1426. .cal_offsets = { 22, 23, 16 } },
  1427. { .dt_id = MT8186_BIG_CPU1,
  1428. .cal_offsets = { 27, 20, 21 } }
  1429. },
  1430. VALID_SENSOR_MAP(1, 1, 0, 0),
  1431. .offset = 0x100,
  1432. },
  1433. {
  1434. .lvts_sensor = {
  1435. { .dt_id = MT8186_NNA,
  1436. .cal_offsets = { 29, 30, 31 } },
  1437. { .dt_id = MT8186_ADSP,
  1438. .cal_offsets = { 34, 35, 28 } },
  1439. { .dt_id = MT8186_GPU,
  1440. .cal_offsets = { 39, 32, 33 } }
  1441. },
  1442. VALID_SENSOR_MAP(1, 1, 1, 0),
  1443. .offset = 0x200,
  1444. }
  1445. };
  1446. static const struct lvts_ctrl_data mt8188_lvts_mcu_data_ctrl[] = {
  1447. {
  1448. .lvts_sensor = {
  1449. { .dt_id = MT8188_MCU_LITTLE_CPU0,
  1450. .cal_offsets = { 22, 23, 24 } },
  1451. { .dt_id = MT8188_MCU_LITTLE_CPU1,
  1452. .cal_offsets = { 25, 26, 27 } },
  1453. { .dt_id = MT8188_MCU_LITTLE_CPU2,
  1454. .cal_offsets = { 28, 29, 30 } },
  1455. { .dt_id = MT8188_MCU_LITTLE_CPU3,
  1456. .cal_offsets = { 31, 32, 33 } },
  1457. },
  1458. VALID_SENSOR_MAP(1, 1, 1, 1),
  1459. .offset = 0x0,
  1460. },
  1461. {
  1462. .lvts_sensor = {
  1463. { .dt_id = MT8188_MCU_BIG_CPU0,
  1464. .cal_offsets = { 34, 35, 36 } },
  1465. { .dt_id = MT8188_MCU_BIG_CPU1,
  1466. .cal_offsets = { 37, 38, 39 } },
  1467. },
  1468. VALID_SENSOR_MAP(1, 1, 0, 0),
  1469. .offset = 0x100,
  1470. }
  1471. };
  1472. static const struct lvts_ctrl_data mt8188_lvts_ap_data_ctrl[] = {
  1473. {
  1474. .lvts_sensor = {
  1475. { /* unused */ },
  1476. { .dt_id = MT8188_AP_APU,
  1477. .cal_offsets = { 40, 41, 42 } },
  1478. },
  1479. VALID_SENSOR_MAP(0, 1, 0, 0),
  1480. .offset = 0x0,
  1481. },
  1482. {
  1483. .lvts_sensor = {
  1484. { .dt_id = MT8188_AP_GPU0,
  1485. .cal_offsets = { 43, 44, 45 } },
  1486. { .dt_id = MT8188_AP_GPU1,
  1487. .cal_offsets = { 46, 47, 48 } },
  1488. { .dt_id = MT8188_AP_ADSP,
  1489. .cal_offsets = { 49, 50, 51 } },
  1490. },
  1491. VALID_SENSOR_MAP(1, 1, 1, 0),
  1492. .offset = 0x100,
  1493. },
  1494. {
  1495. .lvts_sensor = {
  1496. { .dt_id = MT8188_AP_VDO,
  1497. .cal_offsets = { 52, 53, 54 } },
  1498. { .dt_id = MT8188_AP_INFRA,
  1499. .cal_offsets = { 55, 56, 57 } },
  1500. },
  1501. VALID_SENSOR_MAP(1, 1, 0, 0),
  1502. .offset = 0x200,
  1503. },
  1504. {
  1505. .lvts_sensor = {
  1506. { .dt_id = MT8188_AP_CAM1,
  1507. .cal_offsets = { 58, 59, 60 } },
  1508. { .dt_id = MT8188_AP_CAM2,
  1509. .cal_offsets = { 61, 62, 63 } },
  1510. },
  1511. VALID_SENSOR_MAP(1, 1, 0, 0),
  1512. .offset = 0x300,
  1513. }
  1514. };
  1515. static const struct lvts_ctrl_data mt8192_lvts_mcu_data_ctrl[] = {
  1516. {
  1517. .lvts_sensor = {
  1518. { .dt_id = MT8192_MCU_BIG_CPU0,
  1519. .cal_offsets = { 0x04, 0x05, 0x06 } },
  1520. { .dt_id = MT8192_MCU_BIG_CPU1,
  1521. .cal_offsets = { 0x08, 0x09, 0x0a } }
  1522. },
  1523. VALID_SENSOR_MAP(1, 1, 0, 0),
  1524. .offset = 0x0,
  1525. .mode = LVTS_MSR_FILTERED_MODE,
  1526. },
  1527. {
  1528. .lvts_sensor = {
  1529. { .dt_id = MT8192_MCU_BIG_CPU2,
  1530. .cal_offsets = { 0x0c, 0x0d, 0x0e } },
  1531. { .dt_id = MT8192_MCU_BIG_CPU3,
  1532. .cal_offsets = { 0x10, 0x11, 0x12 } }
  1533. },
  1534. VALID_SENSOR_MAP(1, 1, 0, 0),
  1535. .offset = 0x100,
  1536. .mode = LVTS_MSR_FILTERED_MODE,
  1537. },
  1538. {
  1539. .lvts_sensor = {
  1540. { .dt_id = MT8192_MCU_LITTLE_CPU0,
  1541. .cal_offsets = { 0x14, 0x15, 0x16 } },
  1542. { .dt_id = MT8192_MCU_LITTLE_CPU1,
  1543. .cal_offsets = { 0x18, 0x19, 0x1a } },
  1544. { .dt_id = MT8192_MCU_LITTLE_CPU2,
  1545. .cal_offsets = { 0x1c, 0x1d, 0x1e } },
  1546. { .dt_id = MT8192_MCU_LITTLE_CPU3,
  1547. .cal_offsets = { 0x20, 0x21, 0x22 } }
  1548. },
  1549. VALID_SENSOR_MAP(1, 1, 1, 1),
  1550. .offset = 0x200,
  1551. .mode = LVTS_MSR_FILTERED_MODE,
  1552. }
  1553. };
  1554. static const struct lvts_ctrl_data mt8192_lvts_ap_data_ctrl[] = {
  1555. {
  1556. .lvts_sensor = {
  1557. { .dt_id = MT8192_AP_VPU0,
  1558. .cal_offsets = { 0x24, 0x25, 0x26 } },
  1559. { .dt_id = MT8192_AP_VPU1,
  1560. .cal_offsets = { 0x28, 0x29, 0x2a } }
  1561. },
  1562. VALID_SENSOR_MAP(1, 1, 0, 0),
  1563. .offset = 0x0,
  1564. },
  1565. {
  1566. .lvts_sensor = {
  1567. { .dt_id = MT8192_AP_GPU0,
  1568. .cal_offsets = { 0x2c, 0x2d, 0x2e } },
  1569. { .dt_id = MT8192_AP_GPU1,
  1570. .cal_offsets = { 0x30, 0x31, 0x32 } }
  1571. },
  1572. VALID_SENSOR_MAP(1, 1, 0, 0),
  1573. .offset = 0x100,
  1574. },
  1575. {
  1576. .lvts_sensor = {
  1577. { .dt_id = MT8192_AP_INFRA,
  1578. .cal_offsets = { 0x34, 0x35, 0x36 } },
  1579. { .dt_id = MT8192_AP_CAM,
  1580. .cal_offsets = { 0x38, 0x39, 0x3a } },
  1581. },
  1582. VALID_SENSOR_MAP(1, 1, 0, 0),
  1583. .offset = 0x200,
  1584. },
  1585. {
  1586. .lvts_sensor = {
  1587. { .dt_id = MT8192_AP_MD0,
  1588. .cal_offsets = { 0x3c, 0x3d, 0x3e } },
  1589. { .dt_id = MT8192_AP_MD1,
  1590. .cal_offsets = { 0x40, 0x41, 0x42 } },
  1591. { .dt_id = MT8192_AP_MD2,
  1592. .cal_offsets = { 0x44, 0x45, 0x46 } }
  1593. },
  1594. VALID_SENSOR_MAP(1, 1, 1, 0),
  1595. .offset = 0x300,
  1596. }
  1597. };
  1598. static const struct lvts_ctrl_data mt8195_lvts_mcu_data_ctrl[] = {
  1599. {
  1600. .lvts_sensor = {
  1601. { .dt_id = MT8195_MCU_BIG_CPU0,
  1602. .cal_offsets = { 0x04, 0x05, 0x06 } },
  1603. { .dt_id = MT8195_MCU_BIG_CPU1,
  1604. .cal_offsets = { 0x07, 0x08, 0x09 } }
  1605. },
  1606. VALID_SENSOR_MAP(1, 1, 0, 0),
  1607. .offset = 0x0,
  1608. },
  1609. {
  1610. .lvts_sensor = {
  1611. { .dt_id = MT8195_MCU_BIG_CPU2,
  1612. .cal_offsets = { 0x0d, 0x0e, 0x0f } },
  1613. { .dt_id = MT8195_MCU_BIG_CPU3,
  1614. .cal_offsets = { 0x10, 0x11, 0x12 } }
  1615. },
  1616. VALID_SENSOR_MAP(1, 1, 0, 0),
  1617. .offset = 0x100,
  1618. },
  1619. {
  1620. .lvts_sensor = {
  1621. { .dt_id = MT8195_MCU_LITTLE_CPU0,
  1622. .cal_offsets = { 0x16, 0x17, 0x18 } },
  1623. { .dt_id = MT8195_MCU_LITTLE_CPU1,
  1624. .cal_offsets = { 0x19, 0x1a, 0x1b } },
  1625. { .dt_id = MT8195_MCU_LITTLE_CPU2,
  1626. .cal_offsets = { 0x1c, 0x1d, 0x1e } },
  1627. { .dt_id = MT8195_MCU_LITTLE_CPU3,
  1628. .cal_offsets = { 0x1f, 0x20, 0x21 } }
  1629. },
  1630. VALID_SENSOR_MAP(1, 1, 1, 1),
  1631. .offset = 0x200,
  1632. }
  1633. };
  1634. static const struct lvts_ctrl_data mt8195_lvts_ap_data_ctrl[] = {
  1635. {
  1636. .lvts_sensor = {
  1637. { .dt_id = MT8195_AP_VPU0,
  1638. .cal_offsets = { 0x25, 0x26, 0x27 } },
  1639. { .dt_id = MT8195_AP_VPU1,
  1640. .cal_offsets = { 0x28, 0x29, 0x2a } }
  1641. },
  1642. VALID_SENSOR_MAP(1, 1, 0, 0),
  1643. .offset = 0x0,
  1644. },
  1645. {
  1646. .lvts_sensor = {
  1647. { .dt_id = MT8195_AP_GPU0,
  1648. .cal_offsets = { 0x2e, 0x2f, 0x30 } },
  1649. { .dt_id = MT8195_AP_GPU1,
  1650. .cal_offsets = { 0x31, 0x32, 0x33 } }
  1651. },
  1652. VALID_SENSOR_MAP(1, 1, 0, 0),
  1653. .offset = 0x100,
  1654. },
  1655. {
  1656. .lvts_sensor = {
  1657. { .dt_id = MT8195_AP_VDEC,
  1658. .cal_offsets = { 0x37, 0x38, 0x39 } },
  1659. { .dt_id = MT8195_AP_IMG,
  1660. .cal_offsets = { 0x3a, 0x3b, 0x3c } },
  1661. { .dt_id = MT8195_AP_INFRA,
  1662. .cal_offsets = { 0x3d, 0x3e, 0x3f } }
  1663. },
  1664. VALID_SENSOR_MAP(1, 1, 1, 0),
  1665. .offset = 0x200,
  1666. },
  1667. {
  1668. .lvts_sensor = {
  1669. { .dt_id = MT8195_AP_CAM0,
  1670. .cal_offsets = { 0x43, 0x44, 0x45 } },
  1671. { .dt_id = MT8195_AP_CAM1,
  1672. .cal_offsets = { 0x46, 0x47, 0x48 } }
  1673. },
  1674. VALID_SENSOR_MAP(1, 1, 0, 0),
  1675. .offset = 0x300,
  1676. }
  1677. };
  1678. static const struct lvts_ctrl_data mt8196_lvts_mcu_data_ctrl[] = {
  1679. {
  1680. .lvts_sensor = {
  1681. { .dt_id = MT8196_MCU_MEDIUM_CPU6_0,
  1682. .cal_offsets = { 0x06, 0x07 } },
  1683. { .dt_id = MT8196_MCU_MEDIUM_CPU6_1,
  1684. .cal_offsets = { 0x04, 0x05 } },
  1685. { .dt_id = MT8196_MCU_DSU2,
  1686. .cal_offsets = { 0x0A, 0x0B } },
  1687. { .dt_id = MT8196_MCU_DSU3,
  1688. .cal_offsets = { 0x08, 0x09 } }
  1689. },
  1690. VALID_SENSOR_MAP(1, 1, 1, 1),
  1691. .offset = 0x0,
  1692. .mode = LVTS_MSR_ATP_MODE,
  1693. },
  1694. {
  1695. .lvts_sensor = {
  1696. { .dt_id = MT8196_MCU_LITTLE_CPU3,
  1697. .cal_offsets = { 0x0E, 0x0F } },
  1698. { .dt_id = MT8196_MCU_LITTLE_CPU0,
  1699. .cal_offsets = { 0x0C, 0x0D } },
  1700. { .dt_id = MT8196_MCU_LITTLE_CPU1,
  1701. .cal_offsets = { 0x12, 0x13 } },
  1702. { .dt_id = MT8196_MCU_LITTLE_CPU2,
  1703. .cal_offsets = { 0x10, 0x11 } }
  1704. },
  1705. VALID_SENSOR_MAP(1, 1, 1, 1),
  1706. .offset = 0x100,
  1707. .mode = LVTS_MSR_ATP_MODE,
  1708. },
  1709. {
  1710. .lvts_sensor = {
  1711. { .dt_id = MT8196_MCU_MEDIUM_CPU4_0,
  1712. .cal_offsets = { 0x16, 0x17 } },
  1713. { .dt_id = MT8196_MCU_MEDIUM_CPU4_1,
  1714. .cal_offsets = { 0x14, 0x15 } },
  1715. { .dt_id = MT8196_MCU_MEDIUM_CPU5_0,
  1716. .cal_offsets = { 0x1A, 0x1B } },
  1717. { .dt_id = MT8196_MCU_MEDIUM_CPU5_1,
  1718. .cal_offsets = { 0x18, 0x19 } }
  1719. },
  1720. VALID_SENSOR_MAP(1, 1, 1, 1),
  1721. .offset = 0x200,
  1722. .mode = LVTS_MSR_ATP_MODE,
  1723. },
  1724. {
  1725. .lvts_sensor = {
  1726. { .dt_id = MT8196_MCU_DSU0,
  1727. .cal_offsets = { 0x1E, 0x1F } },
  1728. { .dt_id = MT8196_MCU_DSU1,
  1729. .cal_offsets = { 0x1C, 0x1D } },
  1730. { .dt_id = MT8196_MCU_BIG_CPU7_0,
  1731. .cal_offsets = { 0x22, 0x23 } },
  1732. { .dt_id = MT8196_MCU_BIG_CPU7_1,
  1733. .cal_offsets = { 0x20, 0x21 } }
  1734. },
  1735. VALID_SENSOR_MAP(1, 1, 1, 1),
  1736. .offset = 0x300,
  1737. .mode = LVTS_MSR_ATP_MODE,
  1738. }
  1739. };
  1740. static const struct lvts_ctrl_data mt8196_lvts_ap_data_ctrl[] = {
  1741. {
  1742. .lvts_sensor = {
  1743. { .dt_id = MT8196_AP_TOP0,
  1744. .cal_offsets = { 0x32, 0x33 } },
  1745. { .dt_id = MT8196_AP_TOP1,
  1746. .cal_offsets = { 0x30, 0x31 } },
  1747. { .dt_id = MT8196_AP_TOP2,
  1748. .cal_offsets = { 0x36, 0x37 } },
  1749. { .dt_id = MT8196_AP_TOP3,
  1750. .cal_offsets = { 0x34, 0x35 } }
  1751. },
  1752. VALID_SENSOR_MAP(1, 1, 1, 1),
  1753. .offset = 0x0,
  1754. .mode = LVTS_MSR_ATP_MODE,
  1755. },
  1756. {
  1757. .lvts_sensor = {
  1758. { .dt_id = MT8196_AP_BOT0,
  1759. .cal_offsets = { 0x3A, 0x3B } },
  1760. { .dt_id = MT8196_AP_BOT1,
  1761. .cal_offsets = { 0x38, 0x39 } },
  1762. { .dt_id = MT8196_AP_BOT2,
  1763. .cal_offsets = { 0x3E, 0x3F } },
  1764. { .dt_id = MT8196_AP_BOT3,
  1765. .cal_offsets = { 0x3C, 0x3D } }
  1766. },
  1767. VALID_SENSOR_MAP(1, 1, 1, 1),
  1768. .offset = 0x100,
  1769. .mode = LVTS_MSR_ATP_MODE,
  1770. }
  1771. };
  1772. static const struct lvts_platform_ops lvts_platform_ops_mt7988 = {
  1773. .lvts_raw_to_temp = lvts_raw_to_temp_mt7988,
  1774. .lvts_temp_to_raw = lvts_temp_to_raw_mt7988,
  1775. };
  1776. static const struct lvts_platform_ops lvts_platform_ops_mt8196 = {
  1777. .lvts_raw_to_temp = lvts_raw_to_temp_mt7988,
  1778. .lvts_temp_to_raw = lvts_temp_to_raw_mt8196,
  1779. };
  1780. static const struct lvts_data mt7987_lvts_ap_data = {
  1781. .lvts_ctrl = mt7987_lvts_ap_data_ctrl,
  1782. .num_lvts_ctrl = ARRAY_SIZE(mt7987_lvts_ap_data_ctrl),
  1783. .conn_cmd = mt7988_conn_cmds,
  1784. .init_cmd = mt7987_init_cmds,
  1785. .num_conn_cmd = ARRAY_SIZE(mt7988_conn_cmds),
  1786. .num_init_cmd = ARRAY_SIZE(mt7987_init_cmds),
  1787. .temp_factor = LVTS_COEFF_A_MT7987,
  1788. .temp_offset = LVTS_COEFF_B_MT7987,
  1789. .gt_calib_bit_offset = 32,
  1790. .def_calibration = 19380,
  1791. };
  1792. static const struct lvts_data mt7988_lvts_ap_data = {
  1793. .lvts_ctrl = mt7988_lvts_ap_data_ctrl,
  1794. .conn_cmd = mt7988_conn_cmds,
  1795. .init_cmd = mt7988_init_cmds,
  1796. .num_lvts_ctrl = ARRAY_SIZE(mt7988_lvts_ap_data_ctrl),
  1797. .num_conn_cmd = ARRAY_SIZE(mt7988_conn_cmds),
  1798. .num_init_cmd = ARRAY_SIZE(mt7988_init_cmds),
  1799. .temp_factor = LVTS_COEFF_A_MT7988,
  1800. .temp_offset = LVTS_COEFF_B_MT7988,
  1801. .gt_calib_bit_offset = 24,
  1802. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1803. .ops = &lvts_platform_ops_mt7988,
  1804. };
  1805. static const struct lvts_data mt8186_lvts_data = {
  1806. .lvts_ctrl = mt8186_lvts_data_ctrl,
  1807. .conn_cmd = default_conn_cmds,
  1808. .init_cmd = default_init_cmds,
  1809. .num_lvts_ctrl = ARRAY_SIZE(mt8186_lvts_data_ctrl),
  1810. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1811. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1812. .temp_factor = LVTS_COEFF_A_MT7988,
  1813. .temp_offset = LVTS_COEFF_B_MT7988,
  1814. .gt_calib_bit_offset = 24,
  1815. .def_calibration = 19000,
  1816. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1817. .ops = &lvts_platform_ops_mt7988,
  1818. };
  1819. static const struct lvts_data mt8188_lvts_mcu_data = {
  1820. .lvts_ctrl = mt8188_lvts_mcu_data_ctrl,
  1821. .conn_cmd = default_conn_cmds,
  1822. .init_cmd = default_init_cmds,
  1823. .num_lvts_ctrl = ARRAY_SIZE(mt8188_lvts_mcu_data_ctrl),
  1824. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1825. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1826. .temp_factor = LVTS_COEFF_A_MT8195,
  1827. .temp_offset = LVTS_COEFF_B_MT8195,
  1828. .gt_calib_bit_offset = 20,
  1829. .def_calibration = 35000,
  1830. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1831. .ops = &lvts_platform_ops_mt7988,
  1832. };
  1833. static const struct lvts_data mt8188_lvts_ap_data = {
  1834. .lvts_ctrl = mt8188_lvts_ap_data_ctrl,
  1835. .conn_cmd = default_conn_cmds,
  1836. .init_cmd = default_init_cmds,
  1837. .num_lvts_ctrl = ARRAY_SIZE(mt8188_lvts_ap_data_ctrl),
  1838. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1839. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1840. .temp_factor = LVTS_COEFF_A_MT8195,
  1841. .temp_offset = LVTS_COEFF_B_MT8195,
  1842. .gt_calib_bit_offset = 20,
  1843. .def_calibration = 35000,
  1844. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1845. .ops = &lvts_platform_ops_mt7988,
  1846. };
  1847. static const struct lvts_data mt8192_lvts_mcu_data = {
  1848. .lvts_ctrl = mt8192_lvts_mcu_data_ctrl,
  1849. .conn_cmd = default_conn_cmds,
  1850. .init_cmd = default_init_cmds,
  1851. .num_lvts_ctrl = ARRAY_SIZE(mt8192_lvts_mcu_data_ctrl),
  1852. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1853. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1854. .temp_factor = LVTS_COEFF_A_MT8195,
  1855. .temp_offset = LVTS_COEFF_B_MT8195,
  1856. .gt_calib_bit_offset = 24,
  1857. .def_calibration = 35000,
  1858. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1859. .ops = &lvts_platform_ops_mt7988,
  1860. };
  1861. static const struct lvts_data mt8192_lvts_ap_data = {
  1862. .lvts_ctrl = mt8192_lvts_ap_data_ctrl,
  1863. .conn_cmd = default_conn_cmds,
  1864. .init_cmd = default_init_cmds,
  1865. .num_lvts_ctrl = ARRAY_SIZE(mt8192_lvts_ap_data_ctrl),
  1866. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1867. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1868. .temp_factor = LVTS_COEFF_A_MT8195,
  1869. .temp_offset = LVTS_COEFF_B_MT8195,
  1870. .gt_calib_bit_offset = 24,
  1871. .def_calibration = 35000,
  1872. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1873. .ops = &lvts_platform_ops_mt7988,
  1874. };
  1875. static const struct lvts_data mt8195_lvts_mcu_data = {
  1876. .lvts_ctrl = mt8195_lvts_mcu_data_ctrl,
  1877. .conn_cmd = default_conn_cmds,
  1878. .init_cmd = default_init_cmds,
  1879. .num_lvts_ctrl = ARRAY_SIZE(mt8195_lvts_mcu_data_ctrl),
  1880. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1881. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1882. .temp_factor = LVTS_COEFF_A_MT8195,
  1883. .temp_offset = LVTS_COEFF_B_MT8195,
  1884. .gt_calib_bit_offset = 24,
  1885. .def_calibration = 35000,
  1886. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1887. .ops = &lvts_platform_ops_mt7988,
  1888. };
  1889. static const struct lvts_data mt8195_lvts_ap_data = {
  1890. .lvts_ctrl = mt8195_lvts_ap_data_ctrl,
  1891. .conn_cmd = default_conn_cmds,
  1892. .init_cmd = default_init_cmds,
  1893. .num_lvts_ctrl = ARRAY_SIZE(mt8195_lvts_ap_data_ctrl),
  1894. .num_conn_cmd = ARRAY_SIZE(default_conn_cmds),
  1895. .num_init_cmd = ARRAY_SIZE(default_init_cmds),
  1896. .temp_factor = LVTS_COEFF_A_MT8195,
  1897. .temp_offset = LVTS_COEFF_B_MT8195,
  1898. .gt_calib_bit_offset = 24,
  1899. .def_calibration = 35000,
  1900. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT7988,
  1901. .ops = &lvts_platform_ops_mt7988,
  1902. };
  1903. static const struct lvts_data mt8196_lvts_mcu_data = {
  1904. .lvts_ctrl = mt8196_lvts_mcu_data_ctrl,
  1905. .num_lvts_ctrl = ARRAY_SIZE(mt8196_lvts_mcu_data_ctrl),
  1906. .temp_factor = LVTS_COEFF_A_MT8196,
  1907. .temp_offset = LVTS_COEFF_B_MT8196,
  1908. .gt_calib_bit_offset = 0,
  1909. .def_calibration = 14437,
  1910. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT8196,
  1911. .msr_offset = LVTS_MSR_OFFSET_MT8196,
  1912. .ops = &lvts_platform_ops_mt8196,
  1913. };
  1914. static const struct lvts_data mt8196_lvts_ap_data = {
  1915. .lvts_ctrl = mt8196_lvts_ap_data_ctrl,
  1916. .num_lvts_ctrl = ARRAY_SIZE(mt8196_lvts_ap_data_ctrl),
  1917. .temp_factor = LVTS_COEFF_A_MT8196,
  1918. .temp_offset = LVTS_COEFF_B_MT8196,
  1919. .gt_calib_bit_offset = 0,
  1920. .def_calibration = 14437,
  1921. .num_cal_offsets = LVTS_NUM_CAL_OFFSETS_MT8196,
  1922. .msr_offset = LVTS_MSR_OFFSET_MT8196,
  1923. .ops = &lvts_platform_ops_mt8196,
  1924. };
  1925. static const struct of_device_id lvts_of_match[] = {
  1926. { .compatible = "mediatek,mt7987-lvts-ap", .data = &mt7987_lvts_ap_data },
  1927. { .compatible = "mediatek,mt7988-lvts-ap", .data = &mt7988_lvts_ap_data },
  1928. { .compatible = "mediatek,mt8186-lvts", .data = &mt8186_lvts_data },
  1929. { .compatible = "mediatek,mt8188-lvts-mcu", .data = &mt8188_lvts_mcu_data },
  1930. { .compatible = "mediatek,mt8188-lvts-ap", .data = &mt8188_lvts_ap_data },
  1931. { .compatible = "mediatek,mt8192-lvts-mcu", .data = &mt8192_lvts_mcu_data },
  1932. { .compatible = "mediatek,mt8192-lvts-ap", .data = &mt8192_lvts_ap_data },
  1933. { .compatible = "mediatek,mt8195-lvts-mcu", .data = &mt8195_lvts_mcu_data },
  1934. { .compatible = "mediatek,mt8195-lvts-ap", .data = &mt8195_lvts_ap_data },
  1935. { .compatible = "mediatek,mt8196-lvts-mcu", .data = &mt8196_lvts_mcu_data },
  1936. { .compatible = "mediatek,mt8196-lvts-ap", .data = &mt8196_lvts_ap_data },
  1937. {},
  1938. };
  1939. MODULE_DEVICE_TABLE(of, lvts_of_match);
  1940. static const struct dev_pm_ops lvts_pm_ops = {
  1941. NOIRQ_SYSTEM_SLEEP_PM_OPS(lvts_suspend, lvts_resume)
  1942. };
  1943. static struct platform_driver lvts_driver = {
  1944. .probe = lvts_probe,
  1945. .remove = lvts_remove,
  1946. .driver = {
  1947. .name = "mtk-lvts-thermal",
  1948. .of_match_table = lvts_of_match,
  1949. .pm = &lvts_pm_ops,
  1950. },
  1951. };
  1952. module_platform_driver(lvts_driver);
  1953. MODULE_AUTHOR("Balsam CHIHI <bchihi@baylibre.com>");
  1954. MODULE_DESCRIPTION("MediaTek LVTS Thermal Driver");
  1955. MODULE_LICENSE("GPL");